erlag Ferdinand Berger & Söhne Ges.m.b.H., Horn, Austria, download unter www.biologiezentrum.a Effect of nitrogen sources on the growth of Pythium aphanidermatum (Edson) Fitz By Rajendra K. Grover and J. S. S i d h u Department of Botany and Plant Pathology, Punjab Agricultural University, Ludhiana (Pb.), India. The damping-off of seedlings and root-rot of various crop plants and vegetables are caused by Pythium aphanidermatum (Edson) Fitz. The disease is both soil borne and seed borne and is world wide in distribution. Information regarding the nutritional studies of Pythium species is very scanty and has been reviewed by Kumar and Grover (1966). The present paper deals with the effect of various nitrogen sources on the growth of P. aphanidermatum. Materials and Methods The culture of P. aphanidermatum was the same as used by K u m a r and Grover (1966). Stock cultures were maintained on Potato dextrose agar medium. The result of preliminary experiments with different basal media and nitrogen sources showed that best growth was obtained after 8 days on a medium containing sucrose 30 g; NaN0 3 2 g; KH 2 PO 4 1 g; MgSO 4.7H 2 O 0.5 g; KC1 0.5 g; FeSO 4 0.01 g; and distilled water to make 1 liter. The nitrogen compounds, organic or inorganic, were added to the basal medium in place of NaNO 3 in amounts calculated to give equivalent concentrations of nitrogen. The composition of casein hydrolysate given by Horrow (1946) was used as a guide in selecting nitrogen concentrations. Amino acids were of reagent grade (B. D. H., London) and casein hydrolysate was supplied by Oxo Ltd., London. The inorganic and other chemicals used for different basal media were of analytical grade supplied by B. D. H., London, or E. Merck & Co., Germany. The ph of all the media was adjusted to 5.5 with 0.1 M HC1 or NaOH, before sterilization. All culture vessels used were of Pyrex glass. The basal medium was made twice the final concentration and 25 ml. aliquots dispensed in each of 250 ml Erlenmeyer flasks. To this calculated amounts of respective nitrogen compounds from stock solutions were added and the total volume of solution per flask was made upto 50 ml. with distilled water. The medium was then sterilized for 20 minutes at 15 lb. pressure. Since the fungus did not sporulate, the inocula- 231
tions were made from 4 days old mycelial cultures growing on 2% plain agar medium. The inoculum for each flask consisted of 4 mycelial disks (5 mm. diameter) cut from the peripheral end of the cultures with sterile cork borer so that actively growing regions of same physiological growth could be obtained. Unless otherwise stated, the cultures were incubated for 7 days at 26 ± 1 C, after which the mycelium from replicate flasks of each treatment were combined, filtered, washed, dried in a hot air oven and finally weighed. The dry weight of the mycelium was taken as a measure of the growth. All the cultures were maintained in triplicate and each experiment was repeated at least twice. Results Effect of different Nitrogen sources: Five inorganic nitrogen compounds along with urea and casein hydrolysate were incorporated in the basal medium as the sole nitrogen source in order to see their effect on growth (Table 1). Table 1. Mycelial dry weight of Pythiwm aphanidermatum on media containing different nitrogen sources. Nitrogen. Nitrogen source Concentration ^ welg Final ph Sodium nitrate Potassium nitrate Potassium nitrite Ammonium chloride Ammonium nitrate Urea Casein hydrolysate 100 100 186 180 0 66 93 136 238 6.6 6.5 5.5 4.8 4.4 4.8 A perusal of Table 1 indicates that organic nitrogen compounds were better sources of nitrogen than nitrate nitrogen or ammonium nitrogen. Nitrite was not utilized by the organism. A downward trend in final ph was observed when amonium or organic nitrogen compounds were used; wheares in the presence of inorganic nitrates the final ph increased. To determine the effect of nitrogen concentration on the growth of P. aphanidermatum, the organism was grown on different concentrations of potassium nitrate, ammonium nitrate and casein hydrolysate. The results are presented in Table 2. 232
Table 2. Mycelial dry weight of Pythium aphanidermatum when grown on media containing different nitrogen concentrations of potassium nitrate, ammonium nitrate or casein hydrolysate. Nitrogen. Nitrogen source Concentration UTy ixg/ml. wei nt - Final ph Potassium nitrate Ammonium nitrate Casein hydrolysate 70 280 350 420 70 280 350 420 50 100 250 500 242 184 135 79 43 101 91 77 65 38 215 240 258 456 6.6 6.4 6.2 5.8 5.4 5.1 5.0 5.0 4.8 4.6 4.5 It may be seen from Table 2 that potassium nitrate and ammonium nitrate when added to the basal medium in different concentrations yielded maximum growth at low concentrations of nitrogen, while with the increase in nitrogen concentration of casein hydrolysate an increase in growth was observed. It became clear that P. aphanidermatum had a great specif ity of nitrogen substrate. Effect of different Amino Acids: Earlier results showed that P. aphanidermatum grew best in the media containing casein hydrolysate. Since casein hydrolysate is a mixture of several amino acids and amides, it was decided to determine the growth response in different amino acids. Ten amino acids were used as a source of nitrogen in the basal medium. All amino acids were used at a rate to give an equivalent of 100 jig/ml of nitrogen in the medium. The results are presented in Table 3. With individual amino acids as the nitrogen source, the growth of P. aphanidermatum was poor in most cases except when DL-aspartic acid or L-asparagine were used in the basal medium (Table 3). Least growth was obtained in the presence of glycine, which normally is a good source of nitrogen for most of the fungi. It was assumed that there might be a difference in the way an amino acid affected the growth of P. aphanidermatum in the presence cf other amino acids in the basal medium. To test this hypothesis the ten amino acids under study were incorporated in the basal medium to give a total of 100 (xg/ml. nitrogen concentration. From these ten amino 233
Table 3. Mycelial dry weigth of Pythium aphanidermatum on media containing different amino acids. A i * Dry weight _,., TT Ammo acid * (me) Final ph DL-aspartic acid 265 5.4 L-asparagine 220 5.4 L-lysine HC1 61 5.8 L-histidine HC1 72 Glycine 48 5.4 p-alanine 66 DL-isoleucine 72 5.4 L-threonine 62 L-tryptophane 76 6.0 DL-methionine 79 * Each amino acid was used at a concentration equivalent to give 100 ug/ml. of nitrogen. acids in the basal medium one was omitted at a time, keeping the total nitrogen concentration the same, and the differences in growth were attributed to the missing amino acid. The results are given in Table 4. Table 4. Mycelial dry weight of Pythium aphanidermatum on media containing different combinations of amino acids. Medium * Complete DL-aspartic acid omitted L-asparagine omitted L-lysine omitted L-histidine omitted Glycine omitted ß-alanine omitted DL-isoleucine omitted L-threonine omitted L-tryptophane omitted DL-methionine omitted Dry weight (mg.) 199 129 182 232 187 179 191 203 281 210 172 Final ph 5.8 6.0 5.8 6.0 5.4 6.2 * The complete medium consisted of ten amino acids, each in equal proportion to make a total of 100 fig N/ml, in the basal medium. It may be seen from Table 4 that there was poor growth of P. aphanidermatum in the absence of DL-aspartic acid. A considerable increase in the mycelial yield of the organism was observed when the medium was devoid of DL-isoleucine, L-lysine or L-tryptophane, which probably acted as inhibitors. The absence of other amino acids indi- 234
vidually from a mixture of ten did not influence the growth rate of the organism. The ph of the medium did not change much after the growth and remained in the optimum range. In another experiment the additive effect of some of the growth inhibiting and growth promoting amino acids was determined by adding these in various combinations. The total nitrogen concentration was kept at 100 jxg/ml. in all cases. The results are presented in Table 5. Table 5. Additive effects of different amino acids on the mycelial dry weight of Pythiv/m aphanidermatwm. Nitrogen source ^ n l g!?" Final P H L-lysine + DL-isoleucine 53 L-lysine + Glycine 49 5.0 L-Iysine + L-histidine 58 L-lysine + L-tryptophane 46 5.3 DL-isoleucine + Glycine 58 5.1 DL-isoleucine + L-histidine 41 6.3 DL-isoleucine + L-threonine - 52 DL-isoleucine + L-tryptophane 50 DL-aspartic acid + L-lysine 163 5.5 DL-aspartic acid + DL-isoleucine 177 5.4 DL-aspartic acid + L-asparagine 235 DL-aspartic acid + L-asparagine + L-lysine 183 5.5 DL-aspartic acid -\- L-asparagine -f- DL-isoleucine 191 L-asparagine -f DL-isoleucine -f- L-lysine 5.8 L-threonine + L-tryptophane + Glycine + + L-histidine 81 6.0 A considerable increase in the yield of fungal mycelium was obtained when the medium contained DL-aspartic acid in combination with L-asparagine. Presence of L-lysine or DL-isoleucine in all combinations reduced the growth. When either of these amino acids were added with DL-aspartic acid or L-asparagine, an additive effect was noted. Combination of other amino acids did not enhance much growth. Discussion. The response of Pythium aphanidennatum, to different nitrogen sources varied considerably. Nitrate nitrogen and amino nitrogen sources supported better growth of the organism than the ammonium nitrogen source, while nitrite nitrogen was not assimilated at all. The toxic effect of nitrite nitrogen in acidic ranges is well known (Lilly and Ba r- n e 11, 1951; Cochrane, 1958). The fact that increased nitrate and 235
ammonium concentrations in the medium decreased the mycelial yield, while increased concentrations of casein hydrolysate enhanced the growth of the organism, indicated the superiority of the amino sources, and not the ammonium or nitrate sources, for the growth of this organism. Saksena, Jain and Jafri (1952) observed that for most of the Pythium species tried by them acetamide, ammonium chloride, sodium nitrate, and urea were poor nitrogen sources, while asparagine and alanine supported good growth. Among the several amino acids tried for the growth of P. aphanidermatum, only aspartic acid and asparagine were best assimilated, while in the presence of other amino acids the growth was poor; least being in glycine. Wolf and S h o u p (1943) observed that some species of Allomyces were unable to assimalate glycine. Aspartic acid and asparagine have been reported to be good sources of nitrogen for several fungi (Wolf, 1949; Pelletier and Keitt, 1954; Lewis, 1957; Grover and Chona, 1960; G rover, 1964). The fact that absence of aspartic acid in a pool of amino acids did not increase the growth of P. aphanidermatum indicated that this organism did not assimilate most of these amino acids properly. It is further strengthened by the fact that several combinations of two or more amino acids did not increase the growth except when aspartic acid or asparagine were added to the medium. Asparagine is a ß-amide of aspartic acid and both of these chemicals, particularly aspartic acid, are prime components of transaminating mechanism in many organisms (Kamin and Handler, 1957). It has been observed that a-keto acids of aspartic acid are prominent intermediates in tricarboxylic cycle, and decarboxylation or transamination of aspartic acid results in many amino acids (Davis, 1955). The selective assimilation of aspartic acid and asparagine by P. aphanidermatum is indicative of such an endogenous mechanism of decarboxylation and transamination in this fungus. Summary. Pythium aphanidermatum assimilated amino and nitrate nitrogen better than ammoniuf nitrogen, while nitrite nitrogen was not utilized. Increased concentration of nitrate or amonium salts decreased the growth, while with the increase in casein hydrolysate concentration increased growth was observed. Among the ten amino acids tried as nitrogen source, only DL-aspartic acid and L-asparagine supported good growth. Poor growth resulted when the fungus was grown on a medium containing all the amino acids except DL-aspartic acid. Combination of various amino acids other than containing DL-aspartic acid and/or L-asparagine did not increase the growth, thus indicating direct assimilation of certain amino acids. 236
erlag Ferdinand Berger & Söhne Ges.m.b.H., Horn, Austria, download unter www.biologiezentrum.a References Cochrane, V. W., 1958: Physiology of Fungi. J. Wiley, N. York. Davis, B. D., 1955: Intermediates in amino acid biosynthesis. Advances in Enzymol. 16, 247 312. Grover, R. K., 1964: The effect of amino acids on growth and sporulation of Aspergillus flavus and their carry-over for subsequent spore germination. New Phytologist 63, 12 20. Grover, R. K. and B. L. C h o n a, 1960: Comparative studies on Sclerotiwm rolfsii Sacc. and Ozonium texanum Neal and Wester var. parasiticum Thirumalachar. Indian Phytopath. 13, 118 129. Horrow, B., 1946: Textbook of Biochemistry. Saunders, Philadelphia. Kamin, H. and P. Handler, 1957: Amino acid and protein metabolism. Ann. Rev. Biochem. 26, 419 490. Kumar, M. and R. K. Grover, 1966: Effect of carbon sources on the growth of Pythium, aphanidermatum (Edson) Fitz. Indian Phytopath. (in press). Lewis, R. W., 1957: Amino acid nutrition of Alternaria solani. Phytopath. 47: 121 124. Lilly, V. G. and H. L. Bar nett, 1951: Physiology of Fungi. McGraw Hill, N. Y. Pelletier, R. L. and G. W. K e i 11, 1954: Venturia inaequalis (Cke.) Wint. VI. Amino acids as source of nitrogen. Amer. J. Bot. 41, 362 371. S a k s e n a, R. K., S. K. J a i n and M. H. J a f r i, 1952: Sulphur and nitrogen requirements of the genus Pythium. J. Indian Bot. Soc. 31, 281 286. Wolf, F. T., 1949: Amino acids in the biosynthesis of Penicillin. Mycologia 41, 403 410. Wolf, F. T. and C. S. Shoup, 1943: The effects of certain sugars and amino acids upon respiration of Allomyces. Mycologia 35, 192 200. 287